Shunzi Li

MRI-Visible Micellar Nanomedicine for Targeted Drug Delivery to Lung Cancer Cells

Polymeric micelles are emerging as a highly integrated nanoplatform for cancer targeting, drug delivery and tumor imaging applications. In this study, we describe a multifunctional micelle (MFM) system that is encoded with a lung cancer-targeting peptide (LCP), and encapsulated with superparamagnetic iron oxide (SPIO) and doxorubicin (Doxo) for MR imaging and therapeutic delivery, respectively. The LCP-encoded MFM showed significantly increased alpha(v)beta(6)-dependent cell targeting in H2009 lung cancer cells over a scrambled peptide (SP)-encoded MFM control as well as in an alpha(v)beta(6)-negative H460 cell control. (3)H-Labeled MFM nanoparticles were used to quantify the time- and dose-dependent cell uptake of MFM nanoparticles with different peptide encoding (LCP vs SP) and surface densities (20% and 40%) in H2009 cells. LCP functionalization of the micelle surface increased uptake of the MFM by more than 3-fold compared to the SP control. These results were confirmed by confocal laser scanning microscopy, which further demonstrated the successful Doxo release from MFM and accumulation in the nucleus. SPIO clustering inside the micelle core resulted in high T(2) relaxivity (>400 Fe mM(-1) s(-1)) of the resulting MFM nanoparticles. T(2)-weighted MRI images showed clear contrast differences between H2009 cells incubated with LCP-encoded MFM over the SP-encoded MFM control. An ATP activity assay showed increased cytotoxicity of LCP-encoded MFM over SP-encoded MFM in H2009 cells (IC(50) values were 28.3 +/- 6.4 nM and 73.6 +/- 6.3 nM, respectively; p < 0.005). The integrated diagnostic and therapeutic design of MFM nanomedicine potentially allows for image-guided, target-specific treatment of lung cancer.

Biopanning of Phage Displayed Peptide Libraries for the Isolation of Cell-Specific Ligands

One limitation in the development of biosensors for the early detection of disease is the availability of high specificity and affinity ligands for biomarkers that are indicative of a pathogenic process. Within the past 10 years, biopanning of phage displayed peptide libraries on intact cells has proven to be a successful route to the identification of cell-specific ligands. The peptides selected from these combinatorial libraries are often able to distinguish between diseased cells and their normal counterparts as well as cells in different activation states. These ligands are small and chemical methodologies are available for regiospecific derivatization. As such, they can be incorporated into a variety of different diagnostic and therapeutic platforms. Here we describe the methods utilized in the selection of peptides from phage displayed libraries by biopanning. In addition, we provide methods for the synthesis of the selected peptides as both monomers and tetramers. Downstream uses for the peptides are illustrated.

From Phage Display to Nanoparticle Delivery: Functionalizing Liposomes with Multivalent Peptides Improves Targeting to a Cancer Biomarker

Phage display is commonly used to isolate peptides that bind to a desired cell type. While chemical synthesis of selected peptides often results in ligands with low affinity, a multivalent tetrameric presentation of the peptides dramatically improves affinity. One of the primary uses of these peptides is conjugation to nanoparticle-based therapeutics for specific delivery to target cell types. We set out to optimize the path from phage display peptide selection to peptide presentation on a nanoparticle surface for targeted delivery. Here, we examine the effects of peptide valency, density, and affinity on nanoparticle delivery and therapeutic efficacy, using the α(v)β(6)-specific H2009.1 peptide as a model phage-selected peptide and liposomal doxorubicin as a model therapeutic nanoparticle. Liposomes displaying the higher affinity multivalent H2009.1 tetrameric peptide demonstrate 5-10-fold higher drug delivery than liposomes displaying the lower affinity monomeric H2009.1 peptide, even when the same number of peptide subunits are displayed on the liposome. Importantly, a 6-fold greater toxicity is observed toward α(v)β(6)-expressing cells for liposomes displaying tetrameric verses monomeric H2009.1 peptides. Additionally, liposomal targeting and toxicity increase with increasing concentrations of H2009.1 tetrameric peptide on the liposome surface. Thus, both the multivalent peptide and the multivalent liposome scaffold work together to increase targeting to α(v)β(6)-expressing cells. This multilayered approach to developing high affinity targeted nanoparticles may improve the utility of moderate affinity peptides. As tetramerization is known to increase affinity for a variety of phage-selected peptides, it is anticipated that the tetrameric scaffold may act as a general method for taking peptides from phage display to nanoparticle display.

Peptide-Targeted Polyglutamic Acid Doxorubicin Conjugates for the Treatment of αvβ6-Positive Cancers

Most chemotherapeutics exert their effects on tumor cells as well as their healthy counterparts, resulting in dose limiting side effects. Cell-specific delivery of therapeutics can increase the therapeutic window for treatment by maintaining the therapeutic efficacy while decreasing the untoward side effects. We have previously identified a peptide, named H2009.1, which binds to the integrin alpha(v)beta(6). Here, we report the synthesis of a peptide targeted polyglutamic acid polymer in which the high affinity alpha(v)beta(6)-specific tetrameric H2009.1 peptide is incorporated via a thioether at the N-terminus of a 15 amino acid polymer of glutamic acid. Doxorubicin is incorporated into the polymer via an acid-labile hydrazone bond. Payloads of four doxorubicin molecules per targeting agent are achieved. The drug is released at pH 4.0 and 5.6 but the conjugate is stable at pH 7.0. The conjugate is selectively internalized into alpha(v)beta(6) positive cells as witnessed by flow cytometric analysis and fluorescent microscopy. Cellular uptake is mediated by the H2009.1 peptide, as no internalization of the doxorubicin-PG polymer is observed when it is conjugated to a scrambled sequence control peptide. Importantly, the conjugate is more cytotoxic toward a targeted cell than a cell line that does not express the integrin.

Synthesis and characterization of a high-affinity αvβ6-specific ligand for in vitro and in vivo applications

The αvβ6 integrin is an attractive therapeutic target for several cancers due to its role in metastasis and its negligible expression in normal tissues. We previously identified a peptide from a phage-displayed peptide library that binds specifically to αvβ6. The tetrameric version of the peptide has higher affinity for its cellular targets than the corresponding monomers. However, the inefficient synthesis limits its clinical potential. We report here a convergent synthesis producing the tetrameric peptide in high yield and purity. The ease of the synthesis allows for rapid optimization of the peptide. We have optimized this αvβ6 integrin–binding peptide, determining the minimal binding domain and valency. Importantly, the half-maximal binding affinity of the optimal peptide for its target cell is in the 40 to 60 pmol/L range, rivaling the affinity of commonly used antibody-targeting reagents. This peptide mediates cell-specific uptake, is functional in diagnostic formats, is stable in sera, and can home to a tumor in an animal. We anticipate that this high-affinity ligand for αvβ6 will find clinical use as a diagnostic and therapeutic reagent. [Mol Cancer Ther 2009;8(5):1239–49]

Dimerization of a Phage-Display Selected Peptide for Imaging of αvβ6- Integrin: Two Approaches to the Multivalent Effect

The integrin αvβ6 is an emerging biomarker for non-small cell lung cancer (NSCLC). An αvβ6-binding peptide was previously selected from a phage-displayed peptide library. Here, we utilize a multivalent design to develop a peptidic probe for positron emission tomography (PET) imaging of αvβ6+ NSCLC tumors. Multimeric presentation of this peptide, RGDLATLRQL, on a bifunctional copper chelator was achieved using two approaches: dimerization of the peptide followed by conjugation to the chelator (H2-D10) and direct presentation of two copies of the peptide on the chelator scaffold (H2-(M10)2). Binding affinities of the divalent peptide conjugates are four-fold higher than their monovalent counterpart (H2-M10), suggestive of multivalent binding. PET imaging using the bivalent 64Cu-labeled conjugates showed rapid and persistent accumulation in αvβ6+ tumors. By contrast, no significant accumulation was observed in αvβ6- tumors. Irrespective of the dimerization approach, all divalent probes showed three-fold higher tumor uptake than the monovalent probe, indicating the role of valency in signal enhancement. However, the divalent probes have elevated uptake in non-target organs, especially the kidneys. To abrogate nonspecific uptake, the peptides N-terminus was acetylated. The resultant bivalent probe, 64Cu- AcD10, showed drastic decrease of kidney accumulation while maintaining tumor uptake. In conclusion, we developed an αvβ6-integrin specific probe with optimized biodistribution for noninvasive PET imaging of NSCLC. Further, we have demonstrated that use of multivalent scaffolds is a plausible method to improve library selected peptides, which would be suboptimal or useless otherwise, for imaging probe development.